Integrated clock gater (ICG) using clock cascode complimentary switch logic

ABSTRACT

Inventive aspects include an integrated clock gater (ICG) circuit having clocked complimentary voltage switched logic (CICG) that delivers high performance while maintaining low power consumption characteristics. The CICG circuit provides a small enable setup time and a small clock-to-enabled-clock delay. A significant reduction in clock power consumption is achieved in both enabled and disabled modes, but particularly in the disabled mode. Complimentary latches work in tandem to latch different voltage levels at different nodes depending on the voltage level of the received clock signal and whether or not an enable signal is asserted. An inverter takes the voltage level from one of the nodes, inverts it, and outputs a gated clock signal. The gated clock signal may be active or quiescent depending on the various voltage levels. Time is “borrowed” from an evaluation window and added to a setup time to provide greater tolerances for receiving the enable signal.

BACKGROUND

The present inventive concepts relate to clock gating, and moreparticularly to an integrated clock gater (ICG) circuit usingcomplimentary switch logic having high performance and low powerconsumption characteristics.

Mobile devices are becoming ubiquitous. Such devices include smartphones, tablets, personal digital assistants (PDAs), notebook computers,and the like. Digital processors are used in such devices for executinglogical instructions. The digital processors operate in response to oneor more clock signals. With each pulse of the clock signal, one or morelogical instructions can be executed or partially executed by theprocessor. In this manner, the mobile devices can perform functions thathave become integral and useful to the personal lives of millions ofpeople.

Typically, clock elements within the processor tend to consumerelatively large amounts of power due to high frequency activity. Toavoid power waste, techniques have been developed to limit highfrequency clock activity. Quite often, one or more state machines orsequential elements within the processor are dormant while waiting forother events to occur. The high frequency clock signal fed to theseelements can be “gated” by clock gating, which sets the gated clock to aquiescent state.

Clock gating is a power mitigation technique that can be accomplishedusing specially designed clock gating cells. When the clock gating cellis enabled, the clock signal is passed from its input clock pin to itsoutput—the enabled clock pin. When the clock gating cell is gated, theoutput clock signal is held in its quiescent state, which is typically alogical value of zero for positive edge-triggered state elements.

FIG. 1 is an example of a conventional clock gating circuit referred toas an enable pre-latched on clock low integrated clock gater circuit,also sometimes referred to as a PREICG circuit. The PREICG circuitincludes an AND gate 125 and a latch 120. The AND gate 125 receives aclock signal CLK 105 and an enable signal EN 115. The latch 120 latchesthe enable signal 115 while CLK 105 is at a logic level 0 state. Theenable signal 115 is considered to be latched once CLK 105 transitionsto a logic level 1 state. The output of latch 120 is EN_LAT 130. Thevalue of EN_LAT 130 does not change while CLK 105 is in a logical 1state. When the EN_LAT 130 signal is asserted, the clock signal CLK 105is passed through the AND gate 125, such that GATED CLK 110 is now anactive clock signal. On the other hand, when the EN_LAT 130 signal isnot asserted, the clock signal CLK 105 is not passed through the ANDgate 125, but instead, the gated clock signal GATED CLK 110 isquiescent.

Some of the disadvantages of the PREICG clock gating circuit includelarge enable setup requirements and high latency (i.e., insertiondelay), which can impact clock uncertainty and can also decrease themaximum possible frequency. In addition, combined with complexcombinations of clock gating, the enable signal can have very littlearrival slack. Moreover, the PREICG clock gating circuit degrades themaximum frequency to about 1 GHz due to high enable setup and insertiontimes.

Another conventional approach is shown in FIG. 2. This type of clockgating circuit is referred to as a pulse-based integrated clock gater(PICG) circuit. The PICG circuit creates an internal pulse that issmaller than the regular clock signal. The internal pulse can have afrequency that is twice that of the regular clock signal. In a criticalpath within certain circuitry of the processor, the performance can bedoubled for a period of time, and then at some point later, theperformance is returned to the normal mode.

As can be seen in FIG. 2, the PICG circuit includes a pulse circuit 245,a latch 220, an inverter 250 and other control elements such astransistors P1, N1 and N2. The pulse circuit 245 includes a delaycircuit 240, a NAND gate 225, and an inverter 230. The width of theinternal pulse is defined by the amount of delay introduced by the delaycircuit 240. The NAND gate 225 receives the clock signal CLK 205 and thedelayed clock signal, and from these signals, produces a pulsed clocksignal CLK 235. The pulsed clock signal CLK 235 controls whether or notthe control transistor N2 is turned on or off. An enable signal 215controls whether or not the transistor N1 is turned on or off. Theregular clock signal CLK 205 controls whether or not the transistor P1is turned on or off.

When the enable signal 215 is not asserted, the transistor N1 remainsturned off, which causes the latch 220 to latch the voltage potential ofnode ‘A’ to a high level (e.g., VDD), despite the ongoing oscillationsof the clock signal CLK 205. The inverter 250 inverts this high level toa low level, which results in the GATED CLK 210 being set to a quiescentstate. Conversely, when the enable signal 215 is asserted, thetransistor N1 is turned on, which causes the flow of electrical currentfrom node ‘A’ to GND to be dependent on transistors N2 and P1. In otherwords, in this state, node ‘A’ swings between VDD and GND at thefrequency of the pulsed clock signal CLK 235. As a result, the gatedclock signal CLK 210 swings between VDD and GND at the frequency of thepulsed clock signal CLK 235, although at an opposite polarity due to theinverter 250.

One of the benefits of the PICG design is that they have a small setuptime. In other words, the enable signal EN 215 can arrive close to therising edge of the clock signal CLK 205. This provides additional cycletime to meet timing on critical paths. However, this comes at theexpense of high power usage because the pulse circuit 245 consumessignificant power and is always on. In other words, the pulse circuit245 itself is never clock gated, but rather, it continually consumesenergy. The PICG circuit power usage is 1.5 times that of the PREICGcircuit when the clock is enabled, and up to 10 times the power usage ofthe PREICG circuit when the clock is in a disabled mode. Consequently,even if the enable signal EN 215 is not asserted, the PICG circuit isalways consuming clock power.

What is needed is an integrated clock gater (ICG) circuit that delivershigh performance and low power consumption. It would also be desirableto provide an ICG circuit having a small enable setup time and a smallclock-to-enabled-clock delay. The inventive concepts disclosed hereinimplement clocked complimentary voltage switched logic within an ICGcircuit (generally referred to herein as a CICG circuit), therebydelivering a significant reduction in clock power consumption in theenabled mode, and a particularly significant reduction in power when inthe disabled mode. Together with related inventive concepts disclosedherein, these and other limitations in the prior art are addressed.

BRIEF SUMMARY

Inventive concepts may include a method for gating a clock signal usingcomplimentary switch logic. The method may include receiving a clocksignal, pre-charging a first node and a second node to a high voltagelevel responsive to the clock signal having a low voltage level;latching, by a first latch, a first node to the low voltage levelresponsive to the clock signal having the high voltage level; andlatching, by a second latch, a second node to the high voltage levelresponsive to the clock signal having the high voltage level. Inaddition to the state of the incoming clock signal, the values that arelatched also dependent on whether or not en enable signal is asserted. Agated clock signal is produced based at least on the voltage level ofthe first node.

The method may further include providing a setup time in which an enablesignal can be received, evaluating voltage levels of the first andsecond nodes within an evaluation window, borrowing time from theevaluation window and adding the borrowed time to the setup time inwhich the enable signal can be received so that additional time isprovided for receiving the enable signal. The complimentary latchesinclude the first and second latches.

The method may further include receiving the enable signal, producing agated clock signal that mimics the clock signal when the enable signalis asserted at the high voltage level, and producing a gated clocksignal that is quiescent after the enable signal is de-asserted at thelow voltage level. When the enable signal is de-asserted at the lowvoltage level, the method may include completing mimicking of an entirepulse of the clock signal in which the de-assertion occurs. Responsiveto the de-assertion of the enable signal, the method may includelatching the first and second nodes to the low voltage level so that theentire pulse of the clock signal is mimicked by the gated clock signal.

The method may further include receiving an assertion of an enablesignal when the clock signal is at the high voltage level, and despitethe assertion of the enable signal, continuing to produce a gated clocksignal that is quiescent.

According to features and principles of the present inventive concepts,an ICG using clock cascade complimentary switch logic may include firstand second pre-charge transistors configured to receive a clock signal,a first node connected to the first pre-charge transistor, the firstpre-charge transistor being configured to pre-charge the first noderesponsive to the clock signal, a second node connected to the secondpre-charge transistor, the second pre-charge transistor being configuredto pre-charge the second node responsive to the clock signal, a firstlatch connected to the first node, and a second latch connected to thesecond node.

The CICG circuit may further include an inverter connected to the firstnode, the inverter being configured to invert a voltage level of thefirst node and to produce a gated clock signal. The CICG circuit mayfurther include an evaluation transistor configured to receive the clocksignal, an enable transistor connected to the evaluation transistor andconfigured to receive an enable signal, and an inverse-enable transistorconnected to the second node and to the evaluation transistor, theinverse-enable transistor being configured to receive an inverted enablesignal. The CICG circuit may further include a control transistorconnected to the first node, the second node, and the enable transistor.The first node may be connected to a gate of the control transistor. Theevaluation transistor may be connected to a low voltage potential. Thefirst and second pre-charge transistors may be connected to a highvoltage potential that is higher than the low voltage potential.

Certain of the inventive features may be best achieved by implementingthem in a processor such as within ARM processor core. Other types ofprocessors can implement the inventive principles disclosed herein. Theinventive concepts may be implemented within processors of a variety ofmobile devices such as smart phones, tablets, notebook computers, or thelike, or in a variety of stationary devices such as desktop computers,routers, or the like.

The inventive principles described and illustrated herein provide asignificant reduction in power consumption while maintaining highperformance.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and additional features and advantages of the presentinventive principles will become more readily apparent from thefollowing detailed description, made with reference to the accompanyingfigures, in which:

FIG. 1 is an example of a clock gating circuit referred to as an enablepre-latched on clock low integrated clock gater circuit, also sometimesreferred to as a PREICG circuit, as known in the related art.

FIG. 2 is an example of another clock gating circuit referred to aspulse-based integrated clock gater circuit, also sometimes referred toas a PICG circuit, as known in the related art.

FIG. 3 is an example circuit diagram of a CICG circuit having clockedcomplimentary voltage switched logic, in accordance with inventiveconcepts.

FIG. 4 is another example circuit diagram of a CICG circuit havingclocked complimentary voltage switched logic, in accordance withinventive concepts.

FIG. 5 is an example waveform timing diagram showing a gated clocksignal activated by an enable signal, relating to the CICG circuits ofFIGS. 3 and/or 4, and in accordance with inventive concepts.

FIG. 6 is another example waveform timing diagram showing a gated clocksignal in a quiescent state responsive to an enable signal, relating tothe CICG circuits of FIGS. 3 and/or 4, and in accordance with inventiveconcepts.

FIG. 7 is yet another example waveform timing diagram showing variouswaveforms associated with the CICG circuits of FIGS. 3 and/or 4, inaccordance with inventive concepts.

FIG. 8 is still another example waveform timing diagram showing variouswaveforms associated with the CICG circuits of FIGS. 3 and/or 4, inaccordance with inventive concepts.

FIG. 9 is another example waveform timing diagram showing variouswaveforms associated with the CICG circuits of FIGS. 3 and/or 4, inaccordance with inventive concepts.

FIG. 10 illustrates a more complex example waveform timing diagramshowing various waveforms associated with the CICG circuits of FIGS. 3and/or 4, in accordance with inventive concepts.

FIGS. 11-16 are schematic diagrams of a various devices in which theprocessor and/or logic having one or more CICG circuit can be embedded,in accordance with inventive concepts.

FIG. 17 is a block diagram of a computing system including a processorand/or logic having one or more CICG circuits according to embodimentsof the inventive concept as disclosed herein.

DETAILED DESCRIPTION

Reference will now be made in detail to embodiments of the inventiveconcept, examples of which are illustrated in the accompanying drawings.In the following detailed description, numerous specific details are setforth to enable a thorough understanding of the inventive concept. Itshould be understood, however, that persons having ordinary skill in theart may practice the inventive concept without these specific details.In other instances, well-known methods, procedures, components,circuits, and networks have not been described in detail so as not tounnecessarily obscure aspects of the embodiments.

It will be understood that, although the terms first, second, etc. maybe used herein to describe various elements, these elements should notbe limited by these terms. These terms are only used to distinguish oneelement from another. For example, a first circuit could be termed asecond circuit, and, similarly, a second circuit could be termed a firstcircuit, without departing from the scope of the inventive concept.

The terminology used in the description of the inventive concept hereinis for the purpose of describing particular embodiments only and is notintended to be limiting of the inventive concept. As used in thedescription of the inventive concept and the appended claims, thesingular forms “a”, “an” and “the” are intended to include the pluralforms as well, unless the context clearly indicates otherwise. It willalso be understood that the term “and/or” as used herein refers to andencompasses any and all possible combinations of one or more of theassociated listed items. It will be further understood that the terms“comprises” and/or “comprising,” when used in this specification,specify the presence of stated features, integers, steps, operations,elements, and/or components, but do not preclude the presence oraddition of one or more other features, integers, steps, operations,elements, components, and/or groups thereof. The components and featuresof the drawings are not necessarily drawn to scale.

The mobile device space demands both high frequency characteristics aswell as low-power characteristics, so that mobile devices can deliverhigh performance without impacting battery life. Significant powersavings are achieved in accordance with inventive principles describedherein, particularly when in a disabled mode. The clocked complimentaryvoltage switched logic ICG circuit (i.e., CICG circuit) described hereinprovides a balance of high performance and low power consumption toeliminate the long standing power and performance gap.

FIG. 3 is an example circuit diagram of a CICG circuit 300 havingclocked complimentary voltage switched logic, in accordance withinventive concepts. The CICG circuit 300 includes two complimentarylatches—latch ‘A’ and latch ‘B.’ With two complimentary latches, ittakes some time for the latches to hit their trip points. This period oftime, sometimes referred to herein as borrowed time, is caused byelectrical momentum and positive feedback between the two latches. It isreferred to herein as “borrowed time” because time is “borrowed” from anevaluation window. The evaluation window is a period of time in whichthe clock signal is high. The borrowed time is added to a setup time inwhich the enable signal can be received so that additional time isprovided for receiving and/or latching the enable signal, as describedin detail below. Moreover, the pulse-based circuit as shown in FIG. 2 iseliminated, thereby significantly reducing power consumption.

The CICG circuit 300 receives a clock signal CLK 305 and outputs a gatedclock signal CLK 310. When the CICG circuit 300 is in an “active” mode,the clock signal CLK 305 is essentially passed through as the gatedclock signal CLK 310. On the other hand, when in a “disabled” mode, thenodes ‘A’ and ‘B’ can be held to a fixed voltage level, whichsignificantly reduces power when in the disabled mode. When in thedisabled mode, the gated clock signal CLK 310 is quiescent, whichusually corresponds to a low level or zero voltage potential level. TheCICG circuit 300 can also receive an enable E 315 signal. The enable E315 signal controls whether the CICG circuit 300 produces an active orquiescent gated clock signal CLK 310.

Initially, in the disabled mode, when the clock signal CLK 305 is at alow level, the evaluation transistor N4 remains turned off and thetransistors P1 and P2 remain turned on. N-type transistors are labeledin the figures as NX. P-type transistors are labeled in the figures asPX. The N-type and P-type transistors can be MOSFET type transistors. Itwill be understood, however, that any suitable transistors andtransistor types can be used.

In such a disabled mode, node ‘A’ and node ‘B’ are each pre-charged to avoltage potential of VDD, which generally corresponds to a high logicallevel. Such pre-charging occurs because there is a high-impedance pathbetween each node and the ground voltage potential (i.e., GND) due tothe evaluation transistor N4 being turned off. Latch ‘A’ latches thevoltage potential VDD at node ‘A.’ Latch ‘B’ latches the voltagepotential VDD at node ‘B.’ Because there are little to no fluctuationsof the voltage levels at nodes ‘A’ and ‘B’ during this mode, very littlepower is consumed. The CICG circuit can remain in the disabled mode forany suitable period of time.

When the clock signal CLK 305 swings to a high level, an evaluation modebegins. Each evaluation mode lasts for the duration of a correspondinghigh level (i.e., evaluation window) of the clock signal CLK 305. Duringthe evaluation mode, the latches ‘A’ and ‘B’ evaluate the voltagepotentials at nodes ‘A’ and ‘B,’ and at least one of the nodes is pulleddown to GND depending on the value and timing of the enable signal E315, as further described in detail below with reference to waveformtiming diagrams.

A detailed description of the structural aspects of the CICG circuit 300is now provided. Latch ‘A’ includes three transistors arranged inseries—P5, P6, and N8. The gate of P5 is “air connected” to node LATB oflatch ‘B.’ In other words, while the line is not shown for the sake ofshowing a cleaner diagram, such connecting line is understood to bepresent. An inverter 330 is disposed between node ‘A’ and the gate ofN8. The gate of P6 is connected to the gate of N8. The source of P5 isconnected to VDD. The source of N8 is connected to the drain of N4.

Latch ‘B’ is structurally similar to Latch ‘A.’ Specifically, latch ‘B’includes three transistors arranged in series—P3, P4, and N7. The gateof P3 is “air connected” to the signal EN that is output from theinverter 325. Another inverter 320 is disposed between node ‘B’ and thegate of N7. The gate of P4 is connected to the gate of N7. The source ofP3 is connected to VDD. The source of N7 is connected to the drain ofN4. One of the latches (e.g., ‘A’ or ‘B’) may be designed to haveslightly slower characteristics than the other.

The pre-charge transistors P1 and P2 are connected to the clock pincarrying the clock signal CLK 305. The sources of the transistors P1 andP2 are connected to VDD and the drains to node ‘B’ and node ‘A,’respectively. The control transistor N2 is disposed between thepre-charge transistor P2 and an enable transistor N3. The gate of thecontrol transistor N2 is connected to node ‘B.’ The gate of the enabletransistor N3 receives the enable signal E 315.

An inverse-enable transistor N1 is disposed between the pre-chargetransistor P1 and the evaluation transistor N4. The gate of theinverse-enable transistor N1 is connected to an output of the inverter325. As such, the gate of the transistor receives the EN signal, whichis the enable signal E 315 inverted.

The latch ‘B’ is connected to node ‘B’ and is configured to evaluate avoltage potential of node ‘B,’ and to latch a voltage level based on theevaluation. Similarly, the latch ‘A’ is connected to node ‘A’ and isconfigured to evaluate a voltage potential of node ‘A,’ and to latch avoltage level based on the evaluation. The state of the clock signal CLK305 and the value and timing of the enable signal E 315 influence howthe latches ‘A’ and ‘B’ evaluate and latch the voltage levels of nodes‘A’ and ‘B.’ In addition, an inverter 335 is connected to node ‘A’ andinverts the voltage level of node ‘A,’ which is output as the gatedclock signal CLK 310. The embodiment shown in FIG. 3 uses P-typetransistors for precharging to a VDD level, and N-type transistors forevaluating to a GND level. However, those ordinarily skilled in the artwill recognize that the circuit can also be implemented using N-typetransistor for precharging to a GND level, and P-type transistors forevaluating to a VDD level. Such an alternative implementation isintended to be covered by the spirit of the embodiment shown in FIG. 4.

FIG. 4 is another example circuit diagram of a CICG circuit 400 havingclocked complimentary voltage switched logic, in accordance withinventive concepts. The CICG circuit 400 is similar to the CICG circuit300 of FIG. 3. As can be seen, the notable difference is that the latchcircuits ‘A’ and ‘B’ are shown as boxes rather than detailed latchcircuits. In some embodiments, at least one of the first and secondlatches comprises capacitive elements and does not comprise transistorsthat can be switched on or off. It will be understood that any suitablelatch types can be used without departing from the inventive conceptsdisclosed herein.

FIG. 5 is an example waveform timing diagram showing a gated clocksignal activated by an enable signal, relating to the CICG circuits ofFIGS. 3 and/or 4, and in accordance with inventive concepts. Thisexample is referred to as “Case 1” and shows a waveform diagram foractivating the gated clock signal CLK 310. As shown in FIG. 5, theenable signal E 315 is asserted (e.g., at 515) before the evaluationwindow 505, which begins at 520 (i.e., at the rising edge of the clocksignal CLK 305).

The enable signal E 315 is de-asserted at 525, which in this case,happens to occur when the clock signal CLK 305 is still high (i.e.,during the evaluation window 507). When, as here, the enable signal E315 is appropriately setup relative to the clock edge (e.g., 520), andeven when the enable signal E 315 turns off (e.g., at 525) while theclock signal 305 is high, then the gated clock signal CLK 310essentially follows or mimics the clock signal CLK 305. After the enablesignal E 315 turns off, and the entire clock pulse 507 is fullypropagated to the gated clock signal CLK 310, then the gated clocksignal CLK 310 returns to a quiescent state. In other words, when theenable signal E 315 is de-asserted, the entire pulse of the clock signalCLK 305 in which the de-assertion occurs is mimicked by the gated clocksignal CLK 310, and thereafter, the gated clock signal CLK 310 returnsto a quiescent state.

Notably, there is a borrowed time period 510 in which the CICG circuitcan determine the value of the enable signal E 315. In other words, theborrowed time period 510 is “borrowed” from the evaluation window 505,and added to a setup time in which the enable signal E 315 can beproperly received, thereby enhancing the performance characteristics andtolerances of the CICG circuit. More specifically, the borrowed timeperiod 510 is made possible due to the trip point difference between thelatch ‘A’ and the latch ‘B.’ Such trip point difference occurs as aresult of the nature of how the complimentary switch logic evaluates andlatches voltage levels at nodes ‘A’ and ‘B’ during the evaluation mode.Because of the beneficial delay caused by the complimentary latchesduring the evaluation and latching phases, the enable signal E 315 hasmore time to be evaluated properly. As a result, the enable signal E 315can arrive later than 515, or in other words, closer to or even afterthe rising edge of the clock signal CLK 305, and still be properlyevaluated.

FIG. 6 is another example waveform timing diagram showing a gated clocksignal in a quiescent state responsive to an enable signal, relating tothe CICG circuits of FIGS. 3 and/or 4, and in accordance with inventiveconcepts.

This example is referred to as “Case 2” and shows a waveform diagram inwhich the gated clock signal CLK 310 is not activated. As shown in FIG.6, the enable signal E 315 is asserted (e.g., at 615) after the risingedge 620 of the clock signal CLK 305. When, as here, the enable signal E315 is turned on after the clock signal 305 is high, then the gatedclock signal CLK 310 remains gated or otherwise remains in a quiescentstate. In some embodiments, only when the enable signal E 315 is turnedon after the clock signal 305 has been high at least as long as orlonger than the borrowed time 510 (of FIG. 5), then the gated clocksignal CLK 310 remains gated or otherwise remains in a quiescent state.In other words, if an assertion of the enable signal E 315 arrives toolate after clock signal CLK 305 transitions from low to high, then thegated clock signal CLK 310 does not follow the clock signal CLK 305,regardless of when the enable signal E 315 is de-asserted (e.g., whichin this case, happens at 625).

FIG. 7 is yet another example waveform timing diagram showing variouswaveforms associated with the CICG circuits of FIGS. 3 and/or 4, inaccordance with inventive concepts. FIG. 7 is similar to FIG. 5, but inaddition, the waveforms for nodes ‘A’ and ‘B’ are shown, along withother notations as described in detail below. Reference is now made toFIGS. 3, 4, and 7.

As shown in FIG. 7, during a disabled mode 735, the clock signal CLK 305is held at a low level, which causes node ‘B’ and node ‘A’ to bepre-charged to a high level. In this example, the enable signal E 315 isthen asserted (e.g., at 715) before the evaluation window 705, whichbegins at 720. The rising edge 720 of the clock signal CLK 305 beginsthe evaluation mode. When the evaluation mode begins, latches ‘A’ and‘B’ evaluate the voltages at nodes ‘A’ and ‘B,’ respectively.

Since in this case, the enable signal E 315 is appropriately setuprelative to the rising edge 720 of the clock signal CLK 305, thefollowing events occur. At 720, the pre-charge transistors P1 and P2 areturned off and the evaluation transistor N4 is turned on. The controltransistor N2 remains turned on because, as mentioned above, node ‘B’ isinitially pre-charged and latched to a high level, which is fed to thegate of N2. The enable transistor N3 also remains turned on because theenable signal E 315 is at a high level. Thus, a conductive path betweennode ‘A’ and GND is formed, which pulls node ‘A’ to a low level.

Meanwhile, the inverse-enable transistor N1 remains turned off becausethe enable signal E 315 is inverted by the inverter 325 and fed to thegate of N1. This creates a high impedance path between node ‘B’ and GND,which causes the voltage potential of node ‘B’ to remain latched at ahigh level. After the latches ‘A’ and ‘B’ have hit their trip point(i.e., their “no turning back” point) at 740, then the voltage levels atnodes ‘A’ and ‘B’ become firmly resolved and latched with node ‘A’ at alow level and node ‘B’ at a high level. The inverter 335 inverts thevoltage potential of node ‘A,’ and as a result, a high level is outputas the gated clock signal CLK 310 as shown at 730, thereby following ormimicking the clock pulse 705.

The enable signal E 315 is de-asserted at 725, which in this case,happens to occur when the clock signal CLK 305 is high (i.e., during theevaluation window 707). When, as here, the enable signal E 315 isappropriately setup relative to the clock edge (e.g., 720), and evenwhen the enable signal E 315 turns off (e.g., at 725) while the clocksignal 305 is high, then the gated clock signal CLK 310 essentiallyfollows or mimics the clock signal CLK 305. In other words, in thisstate, node ‘A’ swings between VDD and GND at the frequency of the clocksignal CLK 305. As a result, the gated clock signal CLK 310 swingsbetween VDD and GND at the frequency of node ‘A,’ although at anopposite polarity due to the inverter 335. After the enable signal E 315turns off, and the entire clock pulse 707 is fully propagated to thegated clock signal CLK 310 (i.e., as pulse 732), then the gated clocksignal CLK 310 returns to a quiescent state. It will be understood thatthe gated clock signal CLK 310 can follow any number of clock cycles ofthe clock signal CLK 305 depending on the value of the enable signal E315.

More specifically, the de-assertion of the enable signal E 315 at 725causes the enable transistor N3 to turn off and the inverse-enabletransistor N1 to turn on. As a result, node ‘B’ is temporarily pulled toGND as shown at 745 because a conductive path is formed from node ‘B’through transistors N1 and N4 to GND. Meanwhile, node ‘A’ remains at alow level because the latch ‘A’ has latched the voltage potential ofnode ‘A’ to the low level, which prevents any glitches in the gatedclock signal CLK 310 that might have otherwise been caused by thede-assertion of the enable signal E 315 during the evaluation window707.

As shown at 730 and 732, the gated clock signal CLK 310 substantiallyfollows or substantially mimics the clock signal CLK 305. This occursbecause nodes ‘A’ and ‘B’ are each pre-charged during each low level ofeach clock cycle of CLK 305, which causes the gated clock signal CLK 310to also be set to the low level. Then, during each evaluation window(e.g., 705, 707, etc.), node ‘A’ is pulled down because, as explainedabove, the asserted enable signal E 315 creates a conductive path toGND. This cycle can repeat indefinitely as long as the enable signal E315 is properly asserted. After the enable signal E 315 is de-asserted,node ‘A’ remains latched at a high level because the enable transistorN3 is turned off. Therefore, the gated clock signal CLK 310 is placed inthe quiescent state.

Notably, there is a borrowed time period 710 similar to the borrowedtime period 510 of FIG. 5. A detailed description of the borrowed time710 is omitted here for the sake of brevity. It will be understood,however, that the borrowed time 710 functions in a similar or samefashion as that of the borrowed time 510.

FIG. 8 is still another example waveform timing diagram showing variouswaveforms associated with the CICG circuits of FIGS. 3 and/or 4, inaccordance with inventive concepts. The primary difference between thewaveform diagram of FIG. 8 relative to the waveform diagram of FIG. 7 isthat the enable signal E 315 is asserted at the same time as the risingedge of the clock signal CLK 305. Reference is now made to FIGS. 3, 4,and 8.

As shown in FIG. 8, during a disabled mode 835, the clock signal CLK 305is held at a low level, which causes node ‘B’ and node ‘A’ to bepre-charged to a high level. In this example, the enable signal E 315 isthen asserted (e.g., at 815) at the same time or substantially the sametime as the beginning 820 of the evaluation window 805. The rising edge820 of the clock signal CLK 305 begins the evaluation mode. When theevaluation mode begins, latches ‘A’ and ‘B’ evaluate the voltages atnodes ‘A’ and ‘B,’ respectively.

In particular, there is a borrowed time period 810 in which the CICGcircuit can determine the value of the enable signal E 315, even whenthe enable signal E 315 is asserted very close to, at the same time as,or even after the rising edge 820 of the clock signal CLK 305. In otherwords, the borrowed time period 810 is “borrowed” from the evaluationwindow 805 and added to the setup time to enhance the performancecharacteristics and tolerances of the CICG circuit. More specifically,the borrowed time period 810 is made possible due to the trip pointdifference between the latch ‘A’ and the latch ‘B.’ Such latch trippoint difference occurs as a result of the nature of how thecomplimentary switch logic evaluates and latches voltage levels at nodes‘A’ and ‘B’ during the evaluation mode.

Because of the beneficial delay caused by the complimentary latchesduring the evaluation and latching phases, the enable signal E 315 hasmore time to be evaluated properly. As a result, the enable signal E 315can arrive closer to or at the same time as the rising edge 820 of theclock signal CLK 305, and still be properly evaluated. In someembodiments, the enable signal E 315 can even arrive after the risingedge 820 of the clock signal CLK 305, and still be properly evaluated.This is referred to as a negative setup time.

Since in this case, the enable signal E 315 is appropriately setuprelative to the rising edge 820 of the clock signal CLK 305, thefollowing events occur. At 820, the pre-charge transistors P1 and P2 areturned off and the evaluation transistor N4 is turned on. The controltransistor N2 remains turned on because, as mentioned above, node ‘B’ isinitially pre-charged and latched to a high level, which is fed to thegate of N2. The enable transistor N3 also remains turned on because theenable signal E 315 is at a high level. Thus, a conductive path betweennode ‘A’ and GND is formed, which pulls node ‘A’ to a low level.

Meanwhile, the inverse-enable transistor N1 remains turned off becausethe enable signal E 315 is inverted by the inverter 325 and fed to thegate of N1. This creates a high impedance path between node ‘B’ and GND,which causes the voltage potential of node ‘B’ to remain latched at ahigh level. After the latches ‘A’ and ‘B’ have hit their trip point(i.e., their “no turning back” point) at 840, then the voltage levels atnodes ‘A’ and ‘B’ become firmly resolved and latched with node ‘A’ at alow level and node ‘B’ at a high level. The inverter 335 inverts thevoltage potential of node ‘A,’ and as a result, a high level is outputas the gated clock signal CLK 310 as shown at 830, thereby following ormimicking the clock pulse 805.

The enable signal E 315 is de-asserted at 825, which in this case,happens to occur when the clock signal CLK 305 is high (i.e., during theevaluation window 807). When, as here, the enable signal E 315 isappropriately setup relative to the clock edge (e.g., 820), and evenwhen the enable signal E 315 turns off (e.g., at 825) while the clocksignal 305 is high, then the gated clock signal CLK 310 essentiallyfollows or mimics the clock signal CLK 305. In other words, in thisstate, node ‘A’ swings between VDD and GND at the frequency of the clocksignal CLK 305. As a result, the gated clock signal CLK 310 swingsbetween VDD and GND at the frequency of node ‘A,’ although at anopposite polarity due to the inverter 335. After the enable signal E 315turns off, and the entire clock pulse 807 is fully propagated to thegated clock signal CLK 310 (i.e., as pulse 832), then the gated clocksignal CLK 310 returns to a quiescent state. It will be understood thatthe gated clock signal CLK 310 can follow any number of clock cycles ofthe clock signal CLK 305 depending on the value of the enable signal E315.

More specifically, the de-assertion of the enable signal E 315 at 825causes the enable transistor N3 to turn off and the inverse-enabletransistor N1 to turn on. As a result, node ‘B’ is temporarily pulled toGND as shown at 845 because a conductive path is formed from node ‘B’through transistors N1 and N4 to GND. Meanwhile, node ‘A’ remains at alow level because the latch ‘A’ has latched the voltage potential ofnode ‘A’ to the low level, which prevents any glitches in the gatedclock signal CLK 310 that might have otherwise been caused by thede-assertion of the enable signal E 315 during the evaluation window807.

As shown at 830 and 832, the gated clock signal CLK 310 substantiallyfollows or substantially mimics the clock signal CLK 305. This occursbecause nodes ‘A’ and ‘B’ are each pre-charged during each low level ofeach clock cycle of CLK 305, which causes the gated clock signal CLK 310to also be set to the low level. Then, during each evaluation window(e.g., 805, 807, etc.), node ‘A’ is pulled down because, as explainedabove, the asserted enable signal E 315 creates a conductive path toGND. This cycle can repeat indefinitely as long as the enable signal E315 is properly asserted. After the enable signal E 315 is de-asserted,node ‘A’ remains latched at a high level because the enable transistorN3 is turned off. Therefore, the gated clock signal CLK 310 is placed inthe quiescent state.

FIG. 9 is another example waveform timing diagram showing variouswaveforms associated with the CICG circuits of FIGS. 3 and/or 4, inaccordance with inventive concepts. FIG. 9 is similar to FIG. 6, but inaddition, the waveforms shown for nodes ‘A’ and ‘B’ are shown, alongwith other notations as described in detail below. Reference is now madeto FIGS. 3, 4, and 9.

As shown in FIG. 9, during a disabled mode 935, the clock signal CLK 305is held at a low level, which causes node ‘B’ and node ‘A’ to bepre-charged to a high level. The rising edge 920 of the clock signal CLK305 begins the evaluation mode. When the evaluation mode begins, latches‘A’ and ‘B’ evaluate the voltages at nodes ‘A’ and ‘B,’ respectively.

In this example, the first evaluation window is 905. Since at this time,the enable signal E 315 is held to a low level, the enable transistor N3remains turned off, and the node ‘A’ remains latched at a high level asshown at 950. As a result, the gated clock CLK 310 remains at a lowlevel as shown at 930 due to the inverter 335.

Nodes ‘A’ and ‘B’ are pre-charged and latched to a high level (e.g.,VDD) when the clock signal CLK 305 swings to a low level. The nextevaluation window is 907, which begins at the rising edge 922 of theclock signal CLK 305. At 922, the pre-charge transistors P1 and P2 areturned off and the evaluation transistor N4 is turned on. The enabletransistor N3 initially remains turned off because the enable signal E315 has not yet arrived. The inverse-enable transistor N1, on the otherhand, initially remains turned on due to the inverter 325. Thus, aconductive path is formed between node ‘B’ and GND, and the latch ‘B’evaluates and latches node ‘B’ at a low level as shown at 945. However,node ‘A’ remains latched at a high level as shown at 952 because of thehigh impedance path between node ‘A’ and GND, despite the ongoingoscillations of the clock signal CLK 305.

After the “no turning back” point, the voltage levels at nodes ‘A’ and‘B’ become firmly resolved and latched with node ‘A’ at a high level andnode ‘B’ at a low level. The inverter 335 inverts the voltage potentialof node ‘A,’ and as a result, a low level is maintained as the gatedclock signal CLK 310.

In this example, the enable signal E 315 is then asserted (e.g., at 915)during the evaluation window 907. In other words, the enable signal E315 is asserted when the clock signal CLK 305 is high. This is similarto Case 2 from FIG. 6. Even though the enable signal E 315 is assertedpart-way through the evaluation window 907, the gated clock CLK 310remains at a low level because of the following events.

The assertion of the enable signal E 315 causes the enable transistor N3to turn on, however, since the node ‘B’ is at a low level (as previouslyindicated at 945), the control transistor N2 remains turned off, andtherefore, a high impedance path still exists between node ‘A’ and GND.For this reason, node ‘A’ remains latched at the high level. And as aresult, the gated clock CLK 310 remains at a low level as shown at 932.

The enable signal E 315 is de-asserted at 925, which in this case,happens to occur when the clock signal CLK 305 is low and when the nodes‘A’ and ‘B’ are being pre-charged. As a result, the de-assertion of theenable signal E 315 has no effect on the gated clock signal CLK 310.Thus, the quiescent state of the gated clock signal CLK 310 ismaintained.

FIG. 10 illustrates a more complex example waveform timing diagramshowing various waveforms associated with the CICG circuits of FIGS. 3and/or 4, in accordance with inventive concepts. This example shows acombination of the Case 1 and Case 2 examples described above. Referenceis now made to FIGS. 3, 4, and 10.

As shown in FIG. 10, during a disabled mode 1035, the clock signal CLK305 is held at a low level, which causes node ‘B’ and node ‘A’ to bepre-charged to a high level. The rising edge 1020 of the clock signalCLK 305 begins the evaluation mode. When the evaluation mode begins,latches ‘A’ and ‘B’ evaluate the voltages at nodes ‘A’ and ‘B,’respectively.

In this example, the first evaluation window is 1005, which begins atthe rising edge 1020 of the clock signal CLK 305. At 1020, thepre-charge transistors P1 and P2 are turned off and the evaluationtransistor N4 is turned on. The enable transistor N3 initially remainsturned off because the enable signal E 315 has not yet arrived. Theinverse-enable transistor N1, on the other hand, initially remainsturned on due to the inverter 325. Thus, a conductive path is formedbetween node ‘B’ and GND, and the latch ‘B’ evaluates and latches node‘B’ at a low level as shown at 1045. However, node ‘A’ remains latchedat a high level because of the high impedance path between node ‘A’ andGND.

After the “no turning back” point at 1045, the voltage levels at nodes‘A’ and ‘B’ are firmly resolved and latched with node ‘A’ at a highlevel and node ‘B’ at a low level. The inverter 335 inverts the voltagepotential of node ‘A,’ and as a result, a low level is maintained as thegated clock signal CLK 310.

In this example, the enable signal E 315 is then asserted (e.g., at1015) during the evaluation window 1005. In other words, the enablesignal E 315 is asserted when the clock signal CLK 305 is high. This issimilar to Case 2 from FIGS. 6 and 9, and therefore, some of the detailsof the process are not repeated.

Here, even though the enable signal E 315 is asserted part-way throughthe evaluation window 1005, the gated clock CLK 310 remains at a lowlevel because of the following events. The assertion of the enablesignal E 315 causes the enable transistor N3 to turn on, however, sincethe node ‘B’ is at a low level (as previously indicated at 1045), thecontrol transistor N2 remains turned off, and therefore, a highimpedance path still exists between node ‘A’ and GND. For this reason,node ‘A’ remains latched at the high level. And as a result, the gatedclock CLK 310 remains at a low level. Since the enable signal E 315 wasnot appropriately setup relative to the rising edge 1020 of the clocksignal CLK 305, the gated clock CLK 310 does not follow the clock signalCLK 305, at least for this clock pulse.

Nevertheless, given that the enable signal E 315 is setup appropriatelyrelative to the next evaluation window 1007 beginning with the risingedge 1022, the gated clock signal CLK 310 is activated and follows orotherwise mimics the clock signal CLK 305, as shown at 1030 and 1032.This is similar to Case 1 described above. The detailed description forthis type of sequence of events is provided above with reference toFIGS. 5 and 7, and therefore, some of the description is not repeatedhere for the sake of brevity.

With regard to the de-assertion of the enable signal E 315 at 1025,which in this case, happens to occur when the clock signal CLK 305 ishigh (i.e., during the evaluation window 1009), a sequence of eventssimilar to that illustrated in FIG. 7 occurs. Even when the enablesignal E 315 turns off (e.g., at 1025) while the clock signal 305 ishigh, the gated clock signal CLK 310 essentially follows or mimics theclock signal CLK 305, at least for that clock pulse. In other words, inthis state, node ‘A’ swings between VDD and GND at the frequency of theclock signal CLK 305. As a result, the gated clock signal CLK 310 swingsbetween VDD and GND at the frequency of node ‘A,’ although at anopposite polarity due to the inverter 335. After the enable signal E 315turns off, and the entire clock pulse 1009 is fully propagated to thegated clock signal CLK 310 (i.e., as pulse 1032), then the gated clocksignal CLK 310 returns to a quiescent state as shown at 1034. It will beunderstood that the gated clock signal CLK 310 can follow any number ofclock cycles of the clock signal CLK 305 depending on the value of theenable signal E 315.

More specifically, the de-assertion of the enable signal E 315 at 1025causes the enable transistor N3 to turn off and the inverse-enabletransistor N1 to turn on. As a result, node ‘B’ is temporarily pulled toGND as shown at 1047 because a conductive path is formed from node ‘B’through transistors N1 and N4 to GND. Meanwhile, node ‘A’ remains at alow level because the latch ‘A’ has latched the voltage potential ofnode ‘A’ to the low level, which prevents any glitches in the gatedclock signal CLK 310 that might have otherwise been caused by thede-assertion of the enable signal E 315 during the evaluation window1009.

As shown at 1030 and 1032, the gated clock signal CLK 310 substantiallyfollows or mimics the clock signal CLK 305. This occurs because nodes‘A’ and ‘B’ are each pre-charged during each low level of each clockcycle of CLK 305, which causes the gated clock signal CLK 310 to also beset to the low level. Then, during each evaluation window (e.g., 1007,1009, etc.), node ‘A’ is pulled down because, as explained above, theasserted enable signal E 315 creates a conductive path to GND. Thiscycle can repeat indefinitely as long as the enable signal E 315 isproperly asserted. After the enable signal E 315 is de-asserted, node‘A’ remains latched at a high level because the enable transistor N3 isturned off. Therefore, the gated clock signal CLK 310 is placed in thequiescent state as illustrated at 1034.

FIGS. 11-16 are schematic diagrams of a various devices in which theprocessor and/or logic having one or more CICG circuit can be embedded,in accordance with inventive concepts.

For example, as can be seen in FIG. 11, smart phone 1115 can includeprocessor and/or logic 1105, which can include one or more CICG circuits1110, as described in detail above. Similarly, the tablet 1215 shown inFIG. 12, the notebook computer 1315 shown in FIG. 13, the mobile phone1415 shown in FIG. 14, the camera 1515 shown in FIG. 15, and the desktopcomputer 1615 shown in FIG. 16 can include one or more CICG circuits1110, as described in detail above. It will be understood that anysuitable device that uses a clock signal can include or otherwiseoperate with one or more CICG circuits 1110, as described in detailabove.

FIG. 17 is a block diagram of a computing system 1700 including aprocessor and/or logic 1730 having one or more CICG circuits 1110according to embodiments of the inventive concept as disclosed herein.Referring to FIG. 17, the computing system 1700 may also include a clock1710, a random access memory (RAM) 1715, a user interface 1720, a modem1725 such as a baseband chipset, and/or automated test equipment (ATE)1735, any or all of which may be electrically coupled to a system bus1705. The processor and/or logic 1730, including the one or more CICGcircuit 1110 as set forth herein, may also be electrically coupled tothe system bus 1705.

Using the inventive concepts described herein, a significant reductionin clock tree power can be achieved with little to no effect onperformance. A balance of performance and low power consumption isachieved. Battery life for mobile devices is therefore extended. All orsubstantially all PICG and PREICG circuits can be replaced with CICGcircuits. Such approach allows high-speed processors, such as ahigh-speed ARM core, to reduce total CPU clock power by up to 30%without degrading the maximum possible frequency. In addition, holdtimes are reduced. Moreover, minimum pulse width requirementspecifications are more readily met. Overall, a more robust clock gatercircuit is provided due to reduced susceptibility to voltage and thermalgradients that otherwise induce variability in timing.

Other advantages include an improved enable-to-enabled-clock delay ofthe CICG circuit relative to the traditional ICG implementations. Thecomplimentary switch logic structure allows pulse-style performancewithout the pulser circuit power penalty. The clock input pin load isalso smaller. The CICG circuit possesses improved power consumptioncharacteristics in comparison to traditional ICG implementations, bothwhen enabled and disabled. When enabled, the dynamic power consumptionis reduced by removing the conventional pulse-based integrated clockgater circuit. A 25% reduction in power, or thereabout, can be achievedwhen in the active or enabled mode. When disabled, the dynamic powerconsumption is also reduced by removing the conventional pulse-basedintegrated clock gater circuit. A 50% reduction in power, or thereabout,can be achieved as a result. Additionally, the CICG circuit reduces theneed for low-voltage instantaneous voltage droop (LV IVD) margin neededin PICG circuits for pulse width variation.

The following discussion is intended to provide a brief, generaldescription of a suitable machine or machines in which certain aspectsof the invention can be implemented. Typically, the machine or machinesinclude a system bus to which is attached processors, memory, e.g.,random access memory (RAM), read-only memory (ROM), or other statepreserving medium, storage devices, a video interface, and input/outputinterface ports. The machine or machines can be controlled, at least inpart, by input from conventional input devices, such as keyboards, mice,etc., as well as by directives received from another machine,interaction with a virtual reality (VR) environment, biometric feedback,or other input signal. As used herein, the term “machine” is intended tobroadly encompass a single machine, a virtual machine, or a system ofcommunicatively coupled machines, virtual machines, or devices operatingtogether. Exemplary machines include computing devices such as personalcomputers, workstations, servers, portable computers, handheld devices,telephones, tablets, etc., as well as transportation devices, such asprivate or public transportation, e.g., automobiles, trains, cabs, etc.

The machine or machines can include embedded controllers, such asprogrammable or non-programmable logic devices or arrays, ApplicationSpecific Integrated Circuits (ASICs), embedded computers, smart cards,and the like. The machine or machines can utilize one or moreconnections to one or more remote machines, such as through a networkinterface, modem, or other communicative coupling. Machines can beinterconnected by way of a physical and/or logical network, such as anintranet, the Internet, local area networks, wide area networks, etc.One skilled in the art will appreciate that network communication canutilize various wired and/or wireless short range or long range carriersand protocols, including radio frequency (RF), satellite, microwave,Institute of Electrical and Electronics Engineers (IEEE) 545.11,Bluetooth®, optical, infrared, cable, laser, etc.

Embodiments of the invention can be described by reference to or inconjunction with associated data including functions, procedures, datastructures, application programs, etc. which when accessed by a machineresults in the machine performing tasks or defining abstract data typesor low-level hardware contexts. Associated data can be stored in, forexample, the volatile and/or non-volatile memory, e.g., RAM, ROM, etc.,or in other storage devices and their associated storage media,including hard-drives, floppy-disks, optical storage, tapes, flashmemory, memory sticks, digital video disks, biological storage, etc.Associated data can be delivered over transmission environments,including the physical and/or logical network, in the form of packets,serial data, parallel data, propagated signals, etc., and can be used ina compressed or encrypted format. Associated data can be used in adistributed environment, and stored locally and/or remotely for machineaccess.

Having described and illustrated the principles of the invention withreference to illustrated embodiments, it will be recognized that theillustrated embodiments can be modified in arrangement and detailwithout departing from such principles, and can be combined in anydesired manner. And although the foregoing discussion has focused onparticular embodiments, other configurations are contemplated. Inparticular, even though expressions such as “according to an embodimentof the invention” or the like are used herein, these phrases are meantto generally reference embodiment possibilities, and are not intended tolimit the invention to particular embodiment configurations. As usedherein, these terms can reference the same or different embodiments thatare combinable into other embodiments.

Embodiments of the invention may include a non-transitorymachine-readable medium comprising instructions executable by one ormore processors, the instructions comprising instructions to perform theelements of the inventive concepts as described herein.

The foregoing illustrative embodiments are not to be construed aslimiting the invention thereof. Although a few embodiments have beendescribed, those skilled in the art will readily appreciate that manymodifications are possible to those embodiments without materiallydeparting from the novel teachings and advantages of the presentdisclosure. Accordingly, all such modifications are intended to beincluded within the scope of this inventive concept as defined in theclaims.

What is claimed is:
 1. A complimentary voltage switched integrated clockgater (CICG) circuit, comprising: a first node configured to pre-chargeto a first voltage level in response to a first level of a clock signaland a first level of an enable signal; a second node configured topre-charge to the first voltage level in response to the first level ofthe clock signal and the first level of the enable signal; a first latchcoupled to the first node, the first latch being configured to latch thefirst node to a second voltage level in response to a second level ofthe clock signal and a second level of the enable signal if the enablesignal transitions to the second level before or at substantially a sametime that the clock signal transitions from the first level to thesecond level; and a second latch coupled to the second node, the secondlatch being configured to latch the second node to the first voltagelevel in response to the second level of the clock signal and the secondlevel of the enable signal if the enable signal transitions to thesecond level before or at substantially the same time that the clocksignal transitions from the first level to the second level.
 2. The CICGcircuit according to claim 1, further comprising an output nodeconfigured to output a gated clock signal corresponding to the clocksignal in response to the second level of the clock signal and thesecond level of the enable signal if the enable signal transitions tothe second level before or at substantially the same time that the clocksignal transitions from the first level to the second level.
 3. The CICGcircuit according to claim 2, wherein the gated clock signal remains atthe first level in response to the second level of the clock signal andthe second level of the enable signal if the enable signal transitionsto the second level after the time that the clock signal transitionsfrom the first level to the second level.
 4. The CICG circuit accordingto claim 3, wherein the first and second latches are part of anintegrated clock gater (ICG) device.
 5. The CICG circuit according toclaim 4, wherein the ICG device is part of a smart phone.
 6. The CICGcircuit according to claim 4, wherein the ICG device is part of atablet.
 7. The CICG circuit according to claim 4, wherein the ICG deviceis part of a notebook computer.
 8. The CICG circuit according to claim4, wherein the ICG device is part of a mobile phone.
 9. The CICG circuitaccording to claim 4, wherein the ICG device is part of a desktopcomputer.
 10. A system for gating a clock signal using complimentaryswitch logic, the system comprising: a system bus; memory connected tothe system bus; a user interface associated with the system bus and thememory; and a processor configured to control the memory and the userinterface via the system bus, the processor comprising at least onecomplimentary voltage switched integrated clock gater (CICG) circuitcomprising: a first node configured to pre-charge to a first voltagelevel in response to a first level of a clock signal and a first levelof an enable signal; a second node configured to pre-charge to the firstvoltage level in response to the first level of the clock signal and thefirst level of the enable signal; a first latch coupled to the firstnode, the first latch being configured to latch the first node to asecond voltage level in response to a second level of the clock signaland a second level of the enable signal if the enable signal transitionsto the second level before or at substantially a same time that theclock signal transitions from the first level to the second level; and asecond latch coupled to the second node, the second latch beingconfigured to latch the second node to the first voltage level inresponse to the second level of the clock signal and the second level ofthe enable signal if the enable signal transitions to the second levelbefore or at substantially the same time that the clock signaltransitions from the first level to the second level.
 11. The systemaccording to claim 10, further comprising an output node configured tooutput a gated clock signal corresponding to the clock signal inresponse to the second level of the clock signal and the second level ofthe enable signal if the enable signal transitions to the second levelbefore or at substantially the same time that the clock signaltransitions from the first level to the second level.
 12. The systemaccording to claim 11, wherein the gated clock signal remains at thefirst level in response to the second level of the clock signal and thesecond level of the enable signal if the enable signal transitions tothe second level after the time that the clock signal transitions fromthe first level to the second level.
 13. The system according to claim12, wherein the first and second latches are part of an integrated clockgater (ICG) device.
 14. The system according to claim 13, wherein theICG device is part of a smart phone.
 15. The system according to claim13, wherein the ICG device is part of a tablet.
 16. The system accordingto claim 13, wherein the ICG device is part of a notebook computer. 17.The system according to claim 13, wherein the ICG device is part of amobile phone.
 18. The system according to claim 13, wherein the ICGdevice is part of a desktop computer.